Optical encoder capable of identifying absolute positions

ABSTRACT

The present disclosure is related to an optical encoder which is configured to provide precise coding reference data by feature recognition technology. To apply the present disclosure, it is not necessary to provide particular dense patterns on a working surface. The precise coding reference data can be generated by detecting surface features of the working surface.

RELATED APPLICATIONS

The present application is a continuation application of U.S. patentapplication Ser. No. 16/447,068 filed on Jun. 20, 2019, which is acontinuation application of U.S. patent application Ser. No. 15/605,487filed on May 25, 2017, which is a continuation-in-part application ofU.S. patent application Ser. No. 15/347,309 filed on Nov. 9, 2016, whichis a continuation-in-part application of U.S. patent application Ser.No. 14/573,023 filed on Dec. 17, 2014, which claims priority toTaiwanese Application Number 103109350, filed Mar. 13, 2014 andTaiwanese Application Number 103118735, filed May 28, 2014, and is acontinuation-in-part application of U.S. patent application Ser. No.15/087,507 filed on Mar. 31, 2016, which claims priority to TaiwaneseApplication Number 104112384, filed Apr. 17, 2015, the disclosures ofwhich are hereby incorporated by reference herein in their entirety.

BACKGROUND 1. Field of the Disclosure

This disclosure is related to an optical encoder capable of identifyingabsolute positions and an operating method thereof that identify theabsolute positions according to the surface feature or the shutterparameter.

2. Description of the Related Art

Conventionally, means for optical encoding generally needs to process aworking surface to have markers with a specific density for reflectinglight or light penetration. Or the encoding is implemented by arranginglight sources in a particular way or controlling the light emittingsequence. For example, U.S. Pat. No. 8,598,509 discloses a plurality oflight sources for emitting light in a particular sequence as well as anencoded working surface with predetermined gaps such that the light canpenetrate the gaps in a predetermined manner to be detected by aphotodetector. The detection result is used to generate the codingreference data, e.g. position data or velocity data of some elements inthe system.

However, in this conventional technology a special processing has to beperformed on the working surface previously such that the applicationthereof is limited. Meanwhile, in order to obtain an accurate detectionresult, the processing of the working surface becomes complicated sothat the difficulty of applying this technology also becomes higher.

SUMMARY

The present disclosure provides an optical encoder including adisplacement generating unit, an optical navigation module and aback-end circuit. The displacement generating unit has a detectionsurface formed with a marker at a reference position, and the marker isdivided into multiple areas, said multiple areas of the marker beingarranged to have a predetermined combination of bright regions and darkregions. The optical navigation module includes a light sensing unit anda processing unit. The light sensing unit is configured to capture animage containing the marker. The processing unit is configured to outputa pulse width modulated (PWM) signal corresponding to the predeterminedcombination of the marker at the reference position on the detectionsurface, wherein the PWM signal has two signal levels corresponding tothe predetermined combination in the captured image. The back-endcircuit is configured to determine an original position of the opticalnavigation module with respect to the detection surface according to theoutputted PWM signal.

The present disclosure further provides an optical encoder including adisplacement generating unit, an optical navigation module and aback-end circuit. The displacement generating unit has a detectionsurface formed with a marker at a reference position, and the marker isdivided into multiple areas, said multiple areas of the marker beingarranged to have a predetermined combination of first blackness regionsand second blackness regions. The optical navigation module includes alight sensing unit and a processing unit. The light sensing unit isconfigured to capture an image containing the marker. The processingunit is configured to output, in a comparison mode, a pulse widthmodulated (PWM) signal corresponding to the predetermined combination ofthe marker at the reference position on the detection surface, whereinthe PWM signal has two signal levels corresponding to the predeterminedcombination in the captured image. The back-end circuit includes amemory and a microcontroller. The memory is configured to store apredetermined PWM signal corresponding to the marker at the referenceposition. The microcontroller is configured to compare the outputted PWMsignal with the predetermined PWM signal to determine an originalposition of the optical navigation module with respect to the detectionsurface.

The present disclosure further provides an optical encoder including adisplacement generating unit, an optical navigation module and aback-end circuit. The displacement generating unit has a detectionsurface formed with a marker at a reference position, and the marker haspatterned lines each formed between a bright region and a dark region ofthe marker. The optical navigation module includes a light sensing unitand a processing unit. The light sensing unit is configured to capturean image by receiving reflected light from the marker. The processingunit is configured to output a pulse width modulated (PWM) signalcorresponding to the marker at the reference position on the detectionsurface, wherein the PWM signal has two signal levels each has a pulsewidth corresponding to a pixel distance between two detected lines inthe captured image or between an edge of the captured image and onedetected line in the captured image. The back-end circuit is configuredto determine an original position of the optical navigation module withrespect to the detection surface according to the outputted PWM signal.

In one aspect, the processing unit is configured to identify theoriginal position and the at least one reference position of theoperation range according to a moving vector, a moving distance, arotation angle or a rotation time.

In one aspect, the processing unit is configured to calculate a positiondifference between the comparison image data and the reference data toaccordingly correct an accumulated error.

In one aspect, the processing unit is configured to identify positionsat which a difference value between the comparison image data and thereference data exceeds an identification threshold as unidentifiedpositions.

To achieve the above objects, at least one frame of image havingfeatures is recorded in the memory unit to be served as a referencebasis in the following encoding process. Especially in the positioncorrection function, an original position can be precisely set or a usermay arbitrarily set the reference position according to the requirement.The image having features may be generated by forming markers on thedetection surface for being detected by a sensing unit or by detectingsurface features using the sensing unit.

The optical encoder of the present disclosure stores at least one frameof image having features or a processed image for indicating a specificposition. Accordingly, when the optical encoder captures the imageagain, a position difference between the two images is reported by usingthe algorithm for being used by a system adopting the optical encoder.The system then fine tunes the position of the hardware so as tomaintain a high accuracy.

When a detection surface has marks for being detected by a sensing unit,features of the markers, e.g. the size and the feature position, have tobe arranged in cooperation with the size and the resolution of thesensing unit of the optical encoder as well as the disposed position ofthe optical encoder. Briefly speaking, the size of the sensing unit hasto cover at least the frame formed by the light reflected from thefeatures of the markers, and the resolution of the sensing unit has tobe able to identify the features in the frame.

Compared to the conventional optical encoder, the optical navigationchip, the optical navigation module and the optical encoder provided bythe present disclosure do not need any optical lens disposed on thelight-emitting unit and the sensing array, and the optical navigationchip, the optical navigation module and the optical encoder cancalculate the relative displacement between the optical navigation chipand the displacement generating unit of the optical encoder based on theimages captured by the sensing array. Because the optical navigationchip, the optical navigation module and the optical encoder do not needthe optical lens, the sizes of the optical navigation chip, the opticalnavigation module and the optical encoder can be reduced formicrominiaturization.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram illustrating an optical encoder accordingto an embodiment of the present disclosure.

FIG. 2 is a schematic diagram illustrating an optical navigation moduleaccording to an embodiment of the present disclosure.

FIG. 3 is a schematic diagram illustrating an optical encoder accordingto another embodiment of the present disclosure.

FIG. 4 is a schematic diagram illustrating an optical encoder accordingto another embodiment of the present disclosure.

FIG. 5 is a schematic diagram illustrating an optical encoder accordingto another embodiment of the present disclosure.

FIG. 6 is one embodiment of the present disclosure.

FIG. 6 a is a schematic diagram of an image captured by the lightsensing unit of FIG. 6 .

FIGS. 7 a to 7 e are flow charts of the present disclosure.

FIGS. 8 a and 8 b are upper views of a working surface respectivelywithout any marker and a few markers to which the present inventionapplies.

FIG. 9 is another embodiment of the present disclosure.

FIG. 10 is a schematic diagram of outputted signals when the presentinvention is applied to a working surface without any marker.

FIG. 11 is a schematic diagram of outputted signals when the presentinvention is applied to a working surface with markers.

FIG. 12 is a schematic diagram of predetermined image feature ranges.

FIG. 13 is a schematic diagram of predetermined shutter parameterranges.

FIG. 14 is a schematic diagram of shutter parameters versus blackness.

FIG. 15 is a flow chart of an operating method of an optical encoderaccording to one embodiment of the present disclosure.

FIGS. 16A and 16B are schematic diagrams of an optical encoder accordingto some embodiments of the present disclosure.

FIG. 17 is a schematic block diagram of an optical encoder according toone embodiment of the present disclosure.

FIG. 18 is a schematic diagram of the arrangement of an optical encoderaccording to one embodiment of the present disclosure.

FIGS. 19A and 19B are schematic diagrams of a captured image and acorresponding PWM signal according to some embodiments of the presentdisclosure.

FIG. 20 is a schematic diagram of a captured image and a correspondingPWM signal according to another embodiment of the present disclosure.

FIG. 21 is schematic diagram of the arrangement of an optical encoderaccording to one embodiment of the present disclosure.

FIG. 22 is a flow chart of an operating method of an optical encoderaccording to one embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENT

The descriptions below include some embodiments of the presentdisclosure and schematic diagrams of user's operation for understandinghow the present disclosure is applied to actual operating conditions. Itshould be noted that in the drawings below elements not related to thetechnology of the present disclosure are omitted. Meanwhile, in order toclearly show the relationship between elements, the scale of elements inthe drawings may not be identical to its actual scale.

Notably, the terms first, second, third, etc., may be used herein todescribe various elements, but these elements should not be affected bysuch terms. Such terminology is used to distinguish one element fromanother. Further, the term “or” as used herein may include any one orcombinations of the associated listed items.

Please refer to FIG. 1 , which is a schematic diagram illustrating anoptical encoder according to an embodiment of the present disclosure.The optical encoder 1 includes an optical navigation module 10 and adisplacement generating unit 11. The optical navigation module 10 isdisposed corresponding to a surface of the displacement generating unit11.

The optical navigation module 10 is configured for operatively providinga light beam and irradiating the surface of the displacement generatingunit 11, and then receiving a reflected light beam which the surface ofthe displacement generating unit 11 reflects. Once every capturinginterval, the optical navigation module 10 captures an image belongingto a part of the surface of the displacement generating unit 11 basedupon the reflected light beam.

The displacement generating unit 11, such as a ring, a slide rail or around tube, can be moved to generate a displacement. In certainapplications, the displacement generating unit 11 cannot be moved, andthe optical navigation module 10 can be moved, such that a relativeposition between the optical navigation module 10 and the displacementgenerating unit 11 changes. A shape of the displacement generating unit11 can change to support different applications.

For example, when the optical navigation module 10 is used in an opticalmouse, the displacement generating unit 11 is a desktop. A user canoperate the optical mouse to generate the displacement, and the opticalnavigation module 10 calculates how much displacement as the opticalmouse moves on the desktop. Or, the optical navigation module 10 can beused in a syringe, and the displacement generating unit 11 is a plungerrod. When the plunger rod is pulled or pushed, the optical navigationmodule 10 can sense the displacement of the plunger rod.

In brief, when the relative position between the optical navigationmodule 10 and the displacement generating unit 11 changes, the opticalnavigation module 10 can determine the displacement of the opticalnavigation module 10 according to the images associated with the surfaceof the displacement generating unit 11, and calculate a relativedisplacement between the optical navigation module 10 and thedisplacement generating unit 11.

In the embodiment, the surface of the displacement generating unit 11does not comprise any specific special pattern. In the event that itcomprises a special pattern, the special pattern could be such as arecognition block, and a light reflection rate of the recognition blockis different from a light reflection rate of the surface or the specialpattern could be such as an etching pattern, and the etching patternwould be below the surface and form a notch. It should be noted that theaforesaid special patterns are just taken as an example, but the presentdisclosure is not limited thereto.

Please refer to FIG. 2 , which is a schematic diagram illustrating anoptical navigation module according to an embodiment of the presentdisclosure. The optical navigation module 10 includes a substrate 100, alight-emitting unit 101 and an optical navigation chip 102. Thelight-emitting unit 101 and the optical navigation chip 102 are disposedon the substrate 100. The substrate 100 is such as a printed circuitboard (PCB). The light-emitting unit 101 is proximate to the opticalnavigation chip 102. A spacing distance between the light-emitting unit101 and the optical navigation chip 102 can be changed based onpractical demands, as long as the optical navigation chip 102 canreceive the reflected light beam provided by the surface of thedisplacement generating unit (as the displacement generating unit 11shown in FIG. 1 ).

The light-emitting unit 101, such as a laser diode or a light emittingdiode, is configured for operatively providing the light beam toirradiate the surface of the displacement generating unit 11. The lightbeam provided by the light-emitting unit 101 has a low divergence angle.Thus, the light-emitting unit 101 does not need an optical lens to focusor expand the light beam for reducing scattering.

When the light-emitting unit 101 is the laser diode, the light-emittingunit 101 provides a laser light beam. The laser light beam with lowdivergence angle is hard to scatter. Hence, the laser diode can be usedin the optical navigation module 10 directly. To put it concretely, thelow divergence angle means that a horizontal divergence angle and avertical divergence angle of the light beam are respectively less than10 degrees and 35 degrees. When the light-emitting unit 101 is the lightemitting diode, the light emitting diode is specially designed forproviding the light beam with low divergence angle.

In brief, the light-emitting unit 101 can be a laser diode, a lightemitting diode or other element which can provide a light beam with lowdivergence angle. Thus, the light-emitting port of the light-emittingunit 101 does not have to dispose an optical lens for focusing the lightbeam. Incidentally, the values of the low divergence angle mentionedabove are just taken as an example, but the present disclosure is notlimited thereto. Those skilled in the art can appropriately adjust thedivergence angle of the light beam based on the divergence angle of thelaser light beam to accomplish the optical navigation module 10mentioned above.

The optical navigation chip includes a sensing array 1020 and adisplacement calculating unit 1021. The sensing array 1020 is coupled tothe displacement calculating unit 1021. The sensing array 1020, such asa Complementary Metal-Oxide Semiconductor (CMOS) image sensing array, ora Charge-coupled Device (CCD) image sensing array, is composed by aplurality of pixels forming a pixel matrix. Due to the opticalnavigation module 10 being disposed corresponding to the surface of thedisplacement generating unit 11, the sensing array 1020 receives thereflected light beam reflected by the surface and captures an imagebelonging to a part of the surface once every capturing interval basedupon the reflected light beam.

As described previously, the light beam provided by the light-emittingunit 101 has a low divergence angle, such that the light beam iscompletely provided to the surface of the displacement generating unit11. On the other hand, the surface of the displacement generating unit11 completely reflects the light beam to the sensing array 1020. Thus,the sensing array 1020 can capture a clear image without setting up anoptical lens to focus the reflected light beam.

Incidentally, light-cohesion of the laser light beam is higher thanlight-cohesion of the light beam provided by the light emitting diode.In the embodiment, the sensing array 1021 can obtain a clearer imagewhen the optical navigation module 10 uses the laser diode as a lightsource.

The displacement calculating unit 1021 having an image processingfunction is configured for operatively receiving the image outputted bythe sensing array 1020, and processes the images. Next, the displacementcalculating unit 1021 calculates a relative displacement between theoptical navigation chip 102 and the surface of the displacementgenerating unit 11 according to the images. The technique related tocalculating the relative displacement is well known to those of ordinaryskill in the art, thus it does not bear repeating herein.

After obtaining the relative displacement between the optical navigationchip 102 and the displacement generating unit 11, the displacementcalculating unit 1021 outputs the calculated result to back-endcircuits. Then the back-end circuits implement a corresponding function,such as moving a cursor of the mouse.

Please refer to FIG. 3 , which is a schematic diagram illustrating anoptical encoder according to another embodiment of the presentdisclosure. The optical encoder 3 also includes an optical navigationmodule 30 and a displacement generating unit 31. Structures andfunctions of the optical navigation module 30 are similar to the opticalnavigation module 10 shown in FIG. 1 , thus their descriptions areomitted, and therefore only differences between them will be describedbelow.

Different from the optical navigation module 10 shown in FIG. 1 , thedisplacement generating unit 31 of the optical encoder 3 is a ring. Theoptical navigation module 30 is disposed corresponding to an externalsurface of the displacement generating unit 31.

For example, the optical encoder 3 is used in a stereo system as avolume control knob. A user can adjust volume of the stereo system byturning the optical encoder 3. The optical navigation module 30 sensesthe external surface of the displacement generating unit 31 to calculatea relative displacement between an optical navigation chip of theoptical navigation module 30 and the external surface of thedisplacement generating unit 31. Next, the optical navigation module 30outputs the calculated relative displacement to a back-end circuit, suchas a host, and then the back-end circuit correspondingly adjusts thevolume of the stereo system.

Such as the embodiment mentioned above, the external surface of thedisplacement generating unit 31 can be a smooth surface without anyspecial pattern or there can be at least one special pattern disposed onthe external surface of the displacement generating unit 31 and theoptical navigation module 30 can calculate the relative displacementbetween the optical navigation module 30 and the displacement generatingunit 31 by using the special pattern.

Notably, in the embodiment, the external surface of the displacementgenerating unit 31 can further include a starting pattern. When thesensing array of the optical navigation module 30 detects the startingpattern, the displacement calculating unit of the optical navigationmodule 30 determines the displacement generating unit 31 has rotated onecycle and returned to a start point (such as the starting pattern).

Please refer to FIG. 4 , which is a schematic diagram illustrating anoptical encoder according to another embodiment of the presentdisclosure. The optical encoder 4 also includes an optical navigationmodule 40 and a displacement generating unit 41. Structures andfunctions of the optical navigation module 40 are similar to the opticalnavigation module 10 shown in FIG. 1 and the optical navigation module30 shown in FIG. 3 , thus their descriptions are omitted, and thereforeonly differences between them will be described below.

The displacement generating unit 41 of the optical encoder 4 is also aring. Different from the optical encoder 3 shown in FIG. 3 , the opticalnavigation module 40 is disposed corresponding to an inner surface ofthe displacement generating unit 41. A flow chart for the opticalnavigation module 40 calculating a relative displacement would besimilar to that for the optical navigation module 30, and furtherdescriptions are therefore omitted.

Please refer to FIG. 5 , which is a schematic diagram illustrating anoptical encoder according to another embodiment of the presentdisclosure. The optical encoder 5 also includes an optical navigationmodule 50 and a displacement generating unit 51. Structures andfunctions of the optical navigation module 50 are similar to the opticalnavigation module 10 shown in FIG. 1 , the optical navigation module 30shown in FIG. 3 and the optical navigation module 40 shown in FIG. 4 ,thus their descriptions are omitted, and therefore only differencesbetween them will be described below.

Different from the optical encoders 1, 3 and 4, the displacementgenerating unit 51 of the optical encoder 5 is a round tube. The opticalnavigation module 50 is disposed corresponding to an external surface ofthe displacement generating unit 51.

For example, the optical encoder 5 is a knob disposed at one side of asmart watch. A user can turn the knob to adjust time or date of thesmart watch. When the knob is turned to generate a displacement, theoptical navigation module 50 detects the external surface of the knob tocalculate a relative displacement between an optical navigation chip ofthe optical navigation module 50 and the external surface of the knob.Next, the optical navigation module 50 outputs the calculated relativedisplacement to a back-end circuit (such as a processor of the smartwatch), such that the back-end circuit correspondingly adjusts the timeor the date of the smart watch.

Such as the embodiment mentioned above, the external surface of thedisplacement generating unit 51 can be a smooth surface without anyspecial pattern or there can be at least one special pattern disposed onthe external surface of the displacement generating unit 51. Theexternal surface of the displacement generating unit 51 can furtherinclude a starting pattern. When the sensing array of the opticalnavigation module 50 detects the starting pattern, the displacementcalculating unit of the optical navigation module 50 determines thedisplacement generating unit 51 has rotated one cycle.

In summary, compared to the conventional optical encoder, the opticalnavigation chip, the optical navigation module and the optical encoderprovided by the present disclosure do not need any optical lens disposedon the light-emitting unit and the sensing array, and the opticalnavigation chip, the optical navigation module and the optical encodercan calculate the relative displacement between the optical navigationchip and the displacement generating unit of the optical encoder basedon the images captured by the sensing array. Because the opticalnavigation chip, the optical navigation module and the optical encoderdo not need the optical lens, the sizes of the optical navigation chip,the optical navigation module and the optical encoder can be reduced formicrominiaturization.

Furthermore, the present disclosure uses the laser diode as the lightresource. Due to the laser light beam provided by the laser diode havinghigh cohesion, high directionality and high light-intensity, the opticalnavigation chip can capture the images with high image clarity. Hence,the optical navigation chip can precisely calculate the relativedisplacement based on the images with high image clarity.

FIG. 6 is one embodiment of the present disclosure. An optical encoder10 of this embodiment is operated similar to the optical navigationmodule 10 of FIGS. 1-2 , and thus the same reference number is usedherein. The optical encoder 10 includes a light emitting unit 101, alight sensing unit 1020 and a processing unit 1021, wherein theprocessing unit 1021 is a digital signal processor (DSP) which operatesusing algorithms implemented by software and/or hardware. The lightsensing unit and processing unit are respectively operated similar tothe sensing array 1020 and displacement calculating unit 1021 in FIG. 2, and thus the same reference numbers are used herein. The lightemitting unit 101 is configured to emit light to a detection surface107, and the light sensing unit 1020 is configured to detect reflectedlight from the detection surface 107 using a shutter parameter togenerate detected signals, wherein the shutter parameter includes atleast one of a shutter speed and a diaphragm. For example, when thedetection surface 107 is a dark surface, the shutter parameter isrelatively high; whereas, when the detection surface 107 is a brightsurface, the shutter parameter is relatively low. The processing unit1021 is configured to decide the shutter parameter Sp and process thedetected signals to generate frame identification results, and the frameprocessing results are stored, for example, in a memory integrated inthe processing unit 1021 or stored in the hardware outside of theoptical encoder through a transmission interface for being accessed inthe following controlling and comparison processes.

The frame processing results include image features such as an imagequality value or a pixel statistic value, wherein the image qualityherein is referred to contrast, roughness, smoothness, directionality orfeature counting such as peaks counting, edges counting, gray valuedifferences counting or the like.

Referring to FIG. 6 a , it is a schematic diagram of an image F, whichincludes 9 pixels P1 to P9, captured by the light sensing unit 1020.However, the pixel number is only intended to illustrate but not tolimit the present disclosure. In one embodiment, the processing unit1021 calculates a gray value difference between adjacent pixels in theimage F. For example, the processing unit 1021 compares gray valuedifferences between each pixel and all pixels adjacent thereto with adifference threshold, and when one gray value difference exceeds (largerthan or equal to) the difference threshold, a count value is added by 1whereas when one gray value difference is smaller than the differencethreshold, the count value is added by 0 or maintained unchanged. Forexample, the processing unit 1021 calculates the gray value differencerespectively between pixels P2, P4, P5 and the pixel P1 and comparesthese gray value differences with the difference threshold, calculatesthe gray value difference respectively between pixels P1, P3 to P6 andthe pixel P2 and compares these gray value differences with thedifference threshold and so on. Accordingly, the processing unit 1021may obtain a count value, as a feature counting, associated with everypixel P1 to P9, and these count values are stored as a digital value. Inanother embodiment, the processing unit 1021 calculates a gray valuedifference between two groups of pixels, e.g. a gray value sum of pixelsP1 and P9, a gray value sum of pixels P3 and P7, and when a differenceof sum between these two gray value sums exceeds a difference threshold,a digital value “0” used as a feature counting may be designated andstored whereas when the difference of sum is smaller than the differencethreshold, a digital value “1” used as a feature counting may bedesignated and stored. In other embodiments, an average gray value ofgray values of each pixel and all pixels adjacent thereto may be storedas a pixel statistic value by digital values. The above stored data isconfigured as reference data for being accessed in the followingcontrolling and comparison processes. In other embodiments, the pixelstatistic is an average gray value of all pixels of the image F. It isappreciated that the reference data of an image being stored is notlimited to those described in the present disclosure as long as theimage feature can be identified.

It should be noted that according to the design of the opticalmechanism, the light emitting unit 101 and the light sensing unit 1020may be arranged in various ways. For example, the two units may bearranged symmetrically to a normal line of a reflective surface suchthat the light sensing unit 1020 may receive the reflected light in anangle symmetrical to that of the light emitting unit 101 emitting light(e.g. referred as a bright field arrangement). Or the light sensing unit1020 may be arranged above the detection surface 107 illuminated by thelight emitting unit 101 so as to receive scattered light from thedetection surface 107 (e.g. referred as a dark field arrangement). Theoptical encoder 10 may have a relative motion with respect to thedetection surface 107. The detection surface 107 is adaptable to variousfields such as the control knob including a volume control knob, atemperature control knob, a moisture control knob and various equipmentknobs, or the linear control including the position control of a printernozzle, the position control of an audio pickup head, the rearviewmirror control and the chair back angle adjustment, but not limitedthereto. These applications have the feature that an original positionor multiple reference positions need to be precisely defined. In theoptical encoder 10, predetermined frame processing results orpredetermined shutter parameter ranges corresponding to the originalposition and every reference position are stored and used as thereference data associated with these positions.

FIGS. 7 a, 7 b, 7 c, 7 d and 7 e are flow charts of an operating methodin applying the present invention. FIG. 7 a shows that in applying thepresent invention, the optical encoder enters a registration mode 212 atfirst and then enters a comparison mode 214. In the registration mode212, the optical encoder records at least one detected signal which isthen frame identified to be served as the reference data or records atleast one shutter parameter range to be served as the reference data.For example, the processing unit 1021 stores the reference dataassociated with at least one reference position on the detection surface107 according to the detected signal or shutter parameter, wherein thereference data includes at least one predetermined image feature rangeor at least one predetermined shutter parameter range. In the comparisonmode 214, the optical encoder compares a frame processing result or acurrent shutter parameter with the reference data so as to identifywhether the optical encoder is at the position corresponding to thereference data, e.g. the original position or one of a plurality ofreference positions mentioned above. For example, the processing unit1021 generates comparison image data according to the detected signal,and compares the comparison image data (i.e. current image data) withthe reference data (i.e. pre-stored image data) so as to determine acurrent position.

In an embodiment of using shutter parameters, the processing unit 1021in the comparison mode 214 compares a current shutter parameter with thepredetermined shutter parameter range to determine a current position,wherein the current shutter parameter is referred to a shutter parameterused by the light sensing unit 1020 for capturing a current image F. Inthis embodiment, the predetermined shutter parameter range is obtained,in the registration mode 212, by adding a predetermined value to andsubtracting a predetermined value from the shutter parametercorresponding to the at least one reference position (e.g., referring toFIG. 13 ), wherein the predetermined value is determined according tothe noise tolerance of system. The added predetermined value may bedifferent from the subtracted predetermined value.

In an embodiment of using image features, the processing unit 1021 inthe comparison mode 214 compares a current image feature with thepredetermined image feature range to determine a current position,wherein the current image feature is referred to an image featureobtained from a current image F captured by the light sensing unit 1020in the comparison mode 214. In this embodiment, the predetermined imagefeature range is obtained, in the registration mode 212, by adding apredetermined value to and subtracting a predetermined value from theimage feature corresponding to the at least one reference position(e.g., referring to FIG. 12 ), wherein the predetermined value isdetermined according to the noise tolerance of system. Similarly, theadded predetermined value may be different from the subtractedpredetermined value.

The circular relative motion between the optical encoder 10 and thedetection surface 107 is taken as an example herein, and the linearrelative motion between the optical encoder 10 and the detection surface107 is similar thereto, e.g. taking one end or the center of a linearregion as an original position.

FIG. 7 b further explains one embodiment of a registration mode, and theoptical encoder 10 rotating on the detection surface 107 is taken as anexample herein. In the registration mode, in the step 222 the opticalencoder 10 rotates on the detection surface 107 to capture images of thedetection surface 107 and calculates moving vectors or moving distancestill a start position is returned. For example, the processing unit 1021calculates difference values between the reference data associated witha start position and the reference data of the followed every image, andwhen the image having the smallest difference value appears again, itmeans that the start position is returned. A range between the startposition being repeatedly detected is referred to an operation range.Then in the step 224, the optical encoder rotates continuously andidentifies a plurality of reference positions (e.g. including theoriginal position and at least one reference position) on the detectionsurface (e.g. the operation range) according to the moving vectors ormoving distances, and detected signals associated with predeterminedpositions are recorded as reference data. For example, a plurality ofpositions may be equally identified on the detection surface 107according to the moving vectors or moving distances within one circlerotation, and the detected signal is recorded when the optical encoderpasses each of the positions to be served as the reference dataassociated with every reference position. Furthermore, in FIG. 7 b anoperation range is determined by repeatedly recognizing an identicalstart position, and then the operation range is equally or unequallydivided using the moving vectors or moving distances.

The purpose of using the moving vectors or moving distances as thedividing reference is due to the non-uniform motion between the opticalencoder 10 and the detection surface 107 in the process of constructingthe reference data of the original position and multiple referencepositions. In order to equally divide the operation range on thedetection surface 107, the moving vectors or moving distances are servedas the dividing reference. In another embodiment, when the relativemotion between the optical encoder 10 and the detection surface 107 is auniform motion (e.g. by electronic automatic control), the detectionsurface 107 may be divided equally or unequally according to a rotationtime or a rotation angle for one circle rotation. In other words, FIG. 7b shows that an operation range is divided using a moving vector, amoving distance, a rotation angle or a rotation time, and the referencedata corresponding to every reference position is stored. Theregistration mode may be executed before shipment of the optical encoder10, by user's selection or when the update of the reference data isidentified necessary by the system itself, so as to store the referencedata corresponding to the original position and every referenceposition.

FIG. 7 c further explains one embodiment of a comparison mode 214.Referring to steps of FIG. 7 b together, in the step 224 of FIG. 7 b ,the optical encoder has generated the reference data of a plurality ofpositions (e.g. including the original position and referencepositions). In the comparison mode, the optical encoder 10 rotates onthe detection surface 107. In the step 232, the optical encoder 10captures images of the detection surface 107 during rotation andaccomplishes the frame processing, e.g. image filtering and digitizing,so as to obtain the comparison image data. It is appreciated that theprocess for generating the comparison image data is preferably identicalto that for generating the reference data, e.g. calculating the grayvalue difference or average gray value of pixels as mentioned above forbeing compared in the following processes. Then in the step 234, theoptical encoder 10 compares the comparison image data with the referencedata and obtains an optimum comparison result. For example, thecomparison result is compared with at least one threshold so as toobtain a digitized comparison result, the maximum comparison resultexceeding the threshold or the minimum comparison result lower than thethreshold is referred as the optimum comparison result to be associatedwith a current position. For example in one embodiment, the differencevalue between the comparison image data and a plurality of referencedata is respectively calculated, and whether the difference valuebetween the comparison image data and the reference data is smaller thana threshold is identified, wherein for example calculating a differencevalue between gray value differences or average gray values of thecomparison image data and that of the reference data. Finally in thestep 236, a current position of the optical encoder 10 corresponding tothe reference data is identified according to the optimum comparisonresult, and the signal is outputted. In other embodiments, thecomparison result may be generated through other ways. For example, theoptical encoder may take a first accurate reference data in thecomparing process as the optimum comparison result. Said threshold maybe a predetermined threshold or dynamically adjusted with the systemoperation.

In another embodiment, in the Step 232 the optical encoder 10 determinesthe shutter parameter for acquiring current images in the rotating. Nextin the Step 234, the optical encoder 10 compares the determined currentshutter parameter with the stored reference data to obtain an optimumcomparison result, e.g., the current shutter parameter within thepredetermined shutter parameter range which is stored in theregistration mode 212. Finally in the Step 236, it is able to identify acurrent position of the optical encoder 10 according to the optimumcomparison result and output a control signal.

In an alternative embodiment, in the Step 232 the optical encoder 10calculates the image feature of the acquired current images in therotating. Next in the Step 234, the optical encoder 10 compares thecalculated current image feature with the stored reference data toobtain an optimum comparison result, e.g., the current image featurewithin the predetermined image feature range which is stored in theregistration mode 212. Finally in the Step 236, it is able to identify acurrent position of the optical encoder 10 according to the optimumcomparison result and output a control signal.

FIG. 7 d further explains one embodiment of a comparison mode withreduced power. According to a previous comparison result, a range of thereference data to be compared is reduced so as to achieve the powersaving. In the step 242, the optical encoder 10 captures images of thedetection surface 107 and accomplishes the frame processing to generatethe comparison image data. In the step 243, the optical encoder 10firstly identifies whether a previous comparison result exists to beserved as a basis in the following comparing process. If a previouscomparison result exists, the reference data in a predetermined range isretrieved from a reference data range represented by the previouscomparison result. And in the step 244, the comparison image data iscompared with the reference data within the predetermined range of theprevious comparison result, and a current comparison result is comparedwith at least one threshold. For example, if the previous comparisonresult is an angle, only a part of reference data within a predeterminedangle range close to said angle is compared. This method may limit thecompared range close to the previous comparison result such that thecomparing process is not performed with all the reference data so as toreduce the calculating amount thereby saving the power and comparisontime. Said predetermined range may be adjusted according to the systemrequirement. If it is necessary to obtain the current comparison resultquickly, the predetermined range may be reduced, or vice versa. Then inthe step 248, the signal is outputted according to the currentcomparison result. If the previous comparison result does not exist,then in the step 246 the comparison image data is compared with all thereference data and a current comparison result is then compared with atleast one threshold so as to obtain an optimum comparison result,similar to the step 234 shown in FIG. 7 c.

FIG. 7 e further explains one embodiment of a comparison mode withcontamination resistant and higher stability. According to the previouscomparison result, it is able to determine whether to update at least apart of the reference data range so as to realize the contaminationresistant and higher stability. After being used for some time, thehardware may be damaged and the detection surface 107 may be polluted tocause the interference to the image capturing of the optical encoder. Itis able to realize the contamination resistant and higher stability byupdating the reference data. When the contamination is formed on thedetection surface 107, the contamination may be treated as a part offeatures of the detection surface 107 different from positions. When thecontamination is formed on the optical encoder 10, a fixed interferenceis formed to influence every image. The above two interferences may beeliminated by updating the reference data range. In the step 252, theoptical encoder 10 captures images of the detection surface 107 andaccomplishes the frame processing so as to generate the comparison imagedata. In the step 261, the optical encoder 10 firstly identifies whetherit is necessary to update the reference data (described below). It thereference data needs to be updated, then after at least a part of thereference data is updated in the step 262, the step 252 is then executedcontinuously. If the reference data needs not to be updated, then in thestep 253 the optical encoder firstly identifies whether a previouscomparison result exists to be served as a basis in the followingcomparing process. If a previous comparison result exists, the referencedata in a predetermined range is retrieved from the reference data rangerepresented by the previous comparison result. And in the step 244, thecomparison image data is compared with the reference data within thepredetermined range of the previous comparison result, and a currentcomparison result is compared with at least one threshold. Then in thestep 258, a control signal is outputted according to the currentcomparison result and whether to update a part of the reference data isdetermined, and then the step 252 is executed continuously. If theprevious comparison result does not exist, then in the step 246 thecomparison image data is compared with all the reference data and acurrent comparison result is compared with at least one threshold so asto obtain an optimum comparison result, similar to the step 234 shown inFIG. 7 c.

In one embodiment, when all the comparison results do not fulfill thecondition limited by the threshold, e.g. the difference value betweenthe comparison image data and the reference data is always larger thanor smaller than a threshold, the current shutter parameter not fallingin the predetermined shutter parameter range or the current imagefeature not falling in the predetermined image feature range, it meansthat the fixed noise in the captured images is high enough to influencethe detection result such that this may be arranged as a condition forupdating at least a part of the reference data, e.g., adjusting boundaryvalues of the predetermined shutter parameter range or the predeterminedimage feature range.

In another embodiment, in the comparison mode 214, even though thecurrent shutter parameter (or current image feature) is within thepredetermined shutter parameter range (or predetermined image featurerange), the current shutter parameter (or current image feature)corresponding to the at least one reference position is always equal toor very close to boundary values (e.g., 1400, 1600, 900, 1100 in FIG. 13) of the predetermined shutter parameter range (or the predeterminedimage feature range), it means that the predetermined shutter parameterrange (or the predetermined image feature range) set before shipment isno longer suitable for the current operating condition or environmentsuch that the processing unit 1021 automatically updates at least a partof the predetermined shutter parameter range (or the predetermined imagefeature range). For example, the registration mode 212 is executed toadd a predetermined value to and subtract a predetermined value from thenew shutter parameter (or image feature) corresponding to the at leastone reference position to obtain the updated predetermined shutterparameter range (or the updated predetermined image feature range). Thepredetermined value is changeable during the updating.

Referring to FIGS. 8 a and 8 b , wherein FIG. 8 a is an upper view ofthe detection surface 302 a without any marker to which the presentdisclosure applies, and FIG. 8 b is an upper view of the detectionsurface 302 a with markers to which the present disclosure applies. InFIG. 8 a , the optical encoder is applied to a knob control, and theoptical encoder 300 rotates with respect to the detection surface 302 a,e.g. one of the optical encoder 300 and the detection surface 302 abeing combined with the rotating mechanism of a knob and the other oneis kept steady. In this manner, when the knob is rotated, a relativerotation occurs between the two elements.

As shown in FIG. 8 a , the optical encoder 300 directly detects surfacefeatures on the detection surface 302 a and generates the frameidentification result. Generally, the surface made of any kind ofmaterial has more or less rugged textures. Therefore, when the opticalencoder 300 emits light to the detection surface 302 a, reflected lightfrom the detection surface 302 a generates bright and dark patternsaccording to the features of the material surface. And these texturesare different from position to position and generally do not repeatedlyappear, and thus different textures can be detected at differentpositions of the detection surface 302 a. It order to prevent errors dueto similar patterns contained in the detected surface image, theexamination and extraction processes may be performed in theregistration mode. In the registration mode, when the optical encoder300 is at the original position (e.g. indicated as 0 degree herein) or aspecific position (e.g. indicated as 45 degrees, 90 degrees, 135degrees, 180 degrees, 225 degrees, 270 degrees or 315 degrees herein)defined by the knob, the frame processing result is recorded to beserved as a comparison reference value (i.e. the reference datamentioned above) for being compared when the optical encoder 300 passesthe positions again. It is appreciated that said specific positions maybe defined according to the moving vector, moving position, rotationtime or rotation angle mentioned above.

The difference between FIG. 8 b and FIG. 8 a is that in FIG. 8 b thedetection surface 302 b has simple markers, e.g. the marker 304 a on thedetection surface 302 b indicating a specific position or angle of theknob such as an original position. In the registration mode, when theoptical encoder 300 firstly detects reflected light from the marker 304a and generates a detected signal, the frame processing result is storedas reference data. Then in the comparison mode, each time when theoptical encoder 300 passes the marker 304 a, the light sensing unit 1020thereof detects the reflected light from the marker 304 a and generatesa detected signal. The processing unit 1021 then generates the frameprocessing result according to the detected signal. As the frameprocessing result includes the feature of the marker 304 a, the opticalencoder 300 then outputs this frame processing result which is thencompared with the reference data to identify whether the knob is rotatedto the original position.

Similarly, the detection surface 302 b may have a plurality of markers,e.g. 304 b, 304 c and so on, to indicate different positions or anglesof the knob. In the comparison mode, when the optical encoder 300 passesthese markers, frame processing results generated by the processing unit1021 include features of each of the markers to identify a currentposition or angle of the knob accordingly.

These positions or angles may be applied to different controls, e.g.different positions indicating different volumes, different adjustingranges and so on. It is appreciated that the number and the position ofthe reference positions in FIGS. 8 a and 8 b may be determined accordingto the required angle resolution and not limited to those described inthe present disclosure.

In another embodiment, the optical encoder 300 pre-stores image featureranges, e.g., image quality range or pixel statistic range,corresponding to the above markers 304 a, 304 b, 304 c (having differentpredetermined blackness) in the registration mode 212. For examplereferring to FIG. 12 , in the registration mode 212 the processing unit1021 determines a predetermined image feature range according to frameprocessing results respectively corresponding to features of eachmarkers 304 a, 304 b, 304 c, e.g., first marker 304 a corresponding to afirst feature range, a second marker 304 b corresponding to a secondfeature range and so on, and positions other than the markerscorresponding to a based feature range. In the comparison mode 214, whenthe processing unit 1021 obtains, according to the frame processingresults, an image feature of a current image within the predeterminedimage feature range, it means that the optical encoder 300 passes or isright above a specific marker such that an absolute position of theoptical encoder 300 is determined. It should be mentioned that althoughFIG. 12 shows that the first and second feature ranges are higher thanthe based feature range, it is not to limit the present disclosure. Inother embodiments, the first and second feature ranges are lower thanthe based feature range as long as the image features corresponding tothe markers are distinguishable from other positions without markers.

In other embodiments, if the optical sensing unit 1020 adopts the autoexposure mechanism and when the optical sensing unit 1020 passes themarkers having different predetermined blackness, the shutter parameterof the optical sensing unit 1020 changes correspondingly. For examplereferring to FIG. 13 , in the registration mode 212, the processing unit1021 sets a predetermined shutter parameter range corresponding to eachmarker, e.g., the marker 304 a corresponding to a first shutterparameter range (e.g., 900-1100), the marker 304 b corresponding to asecond shutter parameter range (e.g., 1400-1600), and positions otherthan the markers corresponding to a based shutter parameter range (e.g.,300-500). In the comparison mode 214, when the processing unit 1021obtains a shutter parameter for capturing a current image within thepredetermined shutter parameter range, it means that the optical encoder300 passes or is right above a specific marker such that an absoluteposition of the optical encoder 300 is determined. For example, when theprocessing unit 1021 determines a current shutter parameter within900-1100, it means that the optical encoder 300 is aligned to the Marker1; when the processing unit 1021 determines a current shutter parameterwithin 1400-1600, it means that the optical encoder 300 is aligned tothe Marker 2; and so on.

Similarly, in FIG. 13 it is possible to set the shutter parameter rangescorresponding to the markers to be lower than the shutter parameterranges at other positions without the markers.

Different markers are arranged with different predetermined blacknesssuch that the processing unit 1021 is able to obtain differentcomparison results according to the frame processing results or shutterparameters. For example referring to FIG. 14 , in an embodiment of usingthe shutter parameter, each blackness is corresponded to one shutterparameter, e.g., shutter speed T1-T11 and/or diaphragm D1-D11, wherein anumber of markers used in an optical encoder 300 is determined accordingto the resolution of the light sensing unit 1020 and the size of thedetection surface 302 b. Accordingly, in the registration mode 212, theprocessing unit 212 stores a plurality of predetermined shutterparameter ranges corresponding to a plurality of reference positions 304a, 304 b and 304 c on the detection surface 302 b, and each of thereference positions 304 a, 304 b and 304 c is disposed with a markerhaving predetermined blackness different from each other as shown inFIG. 14 . In the comparison mode 214, the processing unit 1021 is ableto identify an absolute position of the optical encoder 300 according toa current shutter parameter within any of the predetermined shutterparameter ranges.

The embodiment of using the image quality or pixel statistics issimilar. For example in the registration mode 212, the processing unit212 stores a plurality of predetermined image feature rangescorresponding to a plurality of reference positions 304 a, 304 b and 304c on the detection surface 302 b, and each of the reference positions304 a, 304 b and 304 c is disposed with a marker having predeterminedblackness different from each other, i.e., the shutter parameter in FIG.14 being replaced by the image feature. In the comparison mode 214, theprocessing unit 1021 only needs to identify whether a current imagefeature falls in any of the predetermined image feature ranges.

Comparing with using the image feature as an identification condition,using the shutter parameter does not need to compare two acquiredimages.

It is possible to manufacture the markers 304 a, 304 b and 304 c by aprinter. For example, it is possible to define a printed marker with theoutput setting (R,G,B)=(0,0,0) of the printer as 100% blackness, definea printed marker with the output setting (R,G,B)=(25,25,25) of theprinter as 90% blackness, . . . , and define a printed marker with theoutput setting (R,G,B)=(255,255,255) of the printer as 0% blackness. Itis appreciated that the above RGB values are defined by the user withoutparticular limitations. Accordingly, corresponding to differentpredetermined blackness, it is possible to obtain different imagefeatures and/or shutter parameters. The manufacturing of the markers 304a, 304 b and 304 c is not limited to that given herein as long asdifferent markers are made with different light reflectivity.

FIG. 9 is another embodiment of the present disclosure, which isdifferent from the embodiment of FIG. 6 in that a memory unit 109 isfurther included in this embodiment. The memory unit 109 is configuredto record at least one frame processing result or shutter parameterinformation (i.e. reference data) to be served as the basis for thefollowing encoding process.

FIG. 10 is a schematic diagram of the signal comparison result when thepresent invention is applied to a detection surface (e.g. 302 a) withoutany marker. Referring to FIG. 8 a together, the transverse axis of FIG.10 indicates rotation angles of a knob and the longitudinal axisindicates the frame identification result generated by the opticalencoder 300, and this result may be represented by various numericalvalues, e.g. a sum of absolute difference (SAD) between the comparisonimage data and the reference data. When the sum of absolute differenceis larger, it means that the current frame identification resultdetected by the optical encoder 300 has a larger difference from thecomparison reference value, i.e. the optical encoder 300 is not at thespecific position to be identified. In the example shown in FIG. 10 , itis assumed that an angle of 20 degrees is the specific position to bealigned by the optical encoder 300. The optical encoder 300 captures aframe (image) when the knob is rotated at the position indicating 20degrees on the detection surface, and the frame identification result isrecorded as a comparison reference value, i.e. performing theregistration mode. Then in the followed comparison mode, when theoptical encoder 300 passes the position of 20 degrees again, the sum ofabsolute difference along the longitudinal axis significantly decreases.It means that the current frame identification result detected by theoptical encoder 300 almost has no difference from the comparisonreference value, i.e. the optical encoder 300 being aligned to theposition of 20 degrees. The similar method may be adapted to theapplication having a plurality of comparison reference values. In oneembodiment, the sum of absolute difference may be compared with anidentification threshold TH1, and when the sum of absolute difference issmaller than the identification threshold TH1, it is able to identifythat the rotation angle is at 20 degrees. In addition, in thisembodiment the optical encoder 300 does not store the reference datacorresponding to other angles. At other angles, as the sums of absolutedifference are larger than the identification threshold TH1, the opticalencoder 300 may define the angles at which the sum of absolutedifference between the comparison image data and the reference dataexceeds the threshold TH1 as unidentified angles or positions. And nocontrol signal is generated corresponding to the unidentified angles orpositions.

In addition, as mentioned above when the sums of absolute differencedetected by the optical detector 300 corresponding to all angles arelarger than the identification threshold TH1, i.e. the sum of absolutedifference between the comparison image data at the current position andthe reference data also exceeding the identification threshold TH1, itmeans that a part of the reference data (e.g. shown in FIG. 7 e ) mayneed to be updated. Then the optical encoder 300 may update the storedreference data. In another embodiment, when the fixed noise increases,the sum of absolute difference corresponding to most angles maydecrease, and thus the update condition may be set as when the sums ofabsolute difference corresponding to a part of angles are smaller thanan update threshold TH2, i.e. the sums of absolute difference between apart of the comparison image data (not at the current position) with thereference data are smaller than the update threshold TH2, the opticalencoder 300 may update at least a part of the reference data beingstored, wherein the number of angles or positions at which the sum ofabsolute difference is smaller than the update threshold TH2 may bedetermined according to the system tolerance.

In addition, when the optical encoder 300 is rotated by a fixed anglestep, an error accumulation may occur when continuously operating in asame rotating direction. For example, FIG. 10 shows that the sum ofabsolute difference at the angle of 20 degrees gradually increasesduring continuous operation, and thus in the comparison mode theprocessing unit 1021 may further calculate a position difference betweenthe comparison image data and the reference data to accordingly correctan accumulated error. For example, it is able to calculate a positiondifference between the optimum comparison image (e.g. at 20 degrees) andthe reference data, and record an accumulated position difference of theposition difference during continuous operation. When the accumulatedposition difference exceeds the fixed angle step, the optical encodermay be corrected by one angle step.

FIG. 11 is a schematic diagram of the signal comparison result when thepresent invention is applied to a detection surface (e.g. 302 b) withthe marker(s). Referring to FIG. 8 b together, the transverse axis ofFIG. 11 indicates rotation angles of a knob and the longitudinal axisindicates the frame processing result generated by the optical encoder300. In applying to the detection surface with the marker (e.g. 302 b),the frame processing result may be represented by various parametervalue, e.g. image features such as average brightness value or imagequality. Corresponding to the material characteristic of the marker, themarker may be arranged to have a specific reflective brightness. Whenthe image features is smaller or larger (e.g. smaller shown in FIG. 11), it means that a current frame detected by the optical encoder 300 isidentified to have the marker, i.e. the optical encoder 300 is at thespecific position to be identified. Similarly, an identificationthreshold TH1 and/or an update threshold TH2 may be set previously inFIG. 11 as the basis for identifying positions (angles) or updatingreference data.

In an embodiment that the longitudinal axis in FIG. 10 indicates theimage feature or shutter parameter, when the optical encoder 300 movesto a specific position to be identified, the amplitude also has asignificant change, e.g., from outside of a predetermined range toentering the predetermined range. Similarly, the optical encoder 300identifies a position corresponding to the current shutter parameter notwithin the predetermined shutter parameter range or a positioncorresponding to the current image feature not within the predeterminedimage feature range as an unidentified angle or position. No controlsignal is generated corresponding to the unidentified angles orpositions. The processing unit 1021 outputs a control signal only whenthe optical encoder 300 moves to opposite to the reference positions.

In applying the present invention, the optical encoder may furtherinclude a memory unit configured to store the frame data and/or frameprocessing result and relative information associated with everyspecific position. For example in the registration mode 212, the opticalencoder 300 captures a frame (image) or determine a shutter parameterwhen the knob is rotated at the position indicating each specificposition on the detection surface (e.g., 302 b), and records the frameprocessing result or shutter parameter as a comparison reference value.When the identification is made according to the image difference, thedifference along the longitudinal axis significantly decreases when theoptical encoder 300 passes each specific position again. It means thatthe current frame processing result detected by the optical encoder 300almost has no difference from the comparison reference value, i.e. theoptical encoder 300 being aligned to each specific position. When theidentification is made according to the predetermined range (e.g.,predetermined shutter parameter range or predetermined image featurerange), the knob is rotated at each specific position when the imagequality, the pixel statistics or shutter parameter is within thepredetermined range. That is, the optical encoder 300 compares an imagequality, pixel statistics and/or shutter parameter of a current imagewith the predetermined range. When the current image quality, pixelstatistics and/or shutter is within a specific predetermined range, anabsolute position is then determined according to the specificpredetermined range within which the current image quality, pixelstatistics and/or shutter is.

Referring to FIG. 15 , it is an operating method of an optical encoderaccording to one embodiment of the present disclosure, which includesthe steps of: storing, in a registration mode, a predetermined shutterparameter range(or a predetermined image feature range) corresponding toat least one reference position on a detection surface according to ashutter parameter for (or an image feature of detected signals generatedby) detecting light reflected from the detection surface (Step S151);and comparing, in a comparison mode, a current shutter parameter (or acurrent image feature) with the predetermined shutter parameter range(or the predetermined image feature range) to determine a currentposition (Step S153), wherein the registration mode is accomplishedbefore shipment, determined by the system itself and/or by a user. Forexample, before shipment the optical encoder of the this embodiment isintegrated with at least one predetermined shutter parameter range or atleast one image feature range depending on the algorithm being adopted.

Step S151: This step is performed as the registration mode 212. As shownin FIG. 12 , the predetermined image feature range is obtained by addinga predetermined value to or subtracting a predetermined value from theimage feature, obtained in the registration mode 212, corresponding toat least one reference position. As show in FIG. 13 , the predeterminedshutter parameter range is obtained by adding a predetermined value toor subtracting a predetermined value from a shutter parameter, obtainedin the registration mode 212, corresponding to at least one referenceposition. As mentioned above, when the detection surface is arrangedwith a plurality of reference positions, each of the reference positionsis disposed with a marker having predetermined blackness different fromeach other. Each marker corresponds to one predetermined shutterparameter range.

Step S153: This step is performed as the comparison mode 214. In thecomparison mode 214, the processing unit 1021 only needs to compare thecurrent image feature with pre-stored image feature range or compare thecurrent shutter parameter with pre-stored parameter range to directlyobtain a current absolute position of the optical encoder.

In addition, in the comparison mode 214, the processing unit 1021further calculates, e.g., by comparing two images F such as calculatingthe correlation, relative displacement according to detected signalsdetected by the light sensing unit 1020. As mentioned above, an erroraccumulation may occur when the optical encoder is continuously operatedin a same rotating direction. Accordingly, when the processing unit 1021detects that a current shutter parameter is within the predeterminedshutter parameter range or a current image feature is within thepredetermined image feature range, the relative displacement is set tozero. As the predetermined shutter parameter range and the predeterminedimage feature range are used to decide absolute positions of the opticalencoder, the error accumulation is avoided by setting the relativedisplacement to zero.

In addition, the optical encoder may further include a wired or wirelesscommunication interface configured to communicate the relativeinformation with other hardware, e.g. activated by receiving a controlsignal from the host or sending the comparison result to other hardware.For example, the reference data may be stored in the optical encoder orin an external host. When the reference data is stored in the opticalencoder, the optical encoder directly identifies the position or angleand outputs a control signal to the controlled device or a host. Whenthe reference data is stored in an external host of the optical encoder,the optical encoder may output the encoded data (i.e. the comparisonimage data) to the host to allow the host to perform the identificationof the position or angle.

In order to apply the present invention to the embodiment that has afaster speed of relative motion with respect to the detection surface,preferably the frame rate of the present invention is higher than 1,000frames per second. Meanwhile, according to different material of thedetection surface, it is able to set different emitting power oremitting frequencies, or adaptively adjust the emitting power oremitting frequency according to the brightness or dark parameterdetected by the light sensing unit.

In applying the present invention, the light sensing unit may include alight sensing array composed of a plurality of sensing pixels, e.g. asquare light sensing matrix composed of 30×30 pixels or a rectangularlight sensing matrix having different side lengths. The actual size ofthe light sensing array is determined according to the pixel number andpixel size, and is adjustable according to the resolution required bythe system.

In other embodiments, the optical sensing matrix may activate ordeactivate a part of sensing pixels according to the system requirement.For example, in a light sensing matrix composed of 36×36 pixels, it isable to activate all sensing pixels or activate only a part of sensingpixels, e.g. a sub-matrix of 18×18 pixels is activated, or to activatesensing pixels separated by one deactivated sensing pixel. In thismanner, although the detectable range or the sensing resolution of thelight sensing matrix is decreased, power consumption is reduced.

It should be mentioned that although a reflective optical encoder istaken as an example in the above embodiments, i.e. the light emittingunit and the light sensing unit arranged at the same side of thedetection surface, a transmissive optical encoder is possible when thedetection surface is made of light transparent or translucent material,i.e. the light emitting unit and the light sensing unit arranged atdifferent sides of the detection surface. In addition to the disposedpositions of the light emitting unit and the light sensing unit aredifferent, the operating method is similar to the above embodiments andthus details thereof are not described herein.

In another embodiment, the special pattern on a detection surface (e.g.,107 in FIG. 6 ) of a displacement generating unit 11/31/41/51 as shownin FIGS. 1 and 3-5 includes at least one marker formed with parallellines, e.g., straight lines or curved lines. The markers are positionedat specific locations (e.g., reference positions) on the detectionsurface 107 of the displacement generating unit 11/31/41/51 to indicateabsolute positions or angles of said specific locations.

For example, referring to FIGS. 16A and 16B, they are schematic diagramsof markers M1 and M2 detected by an optical navigation module 10 (e.g.,in FIG. 2 ) according to some embodiments of the present disclosure. Asmentioned above, the optical navigation chip 102 includes a lightsensing unit 1020 and a processing unit 1021, wherein details of thelight sensing unit 1020 and the processing unit 1021 are similar tothose mentioned above, only the image feature obtained by the processingunit 1021 in this embodiment is a pulse width modulated (PWM) signal.For example, the optical navigation chip 102 further has an additionalpin 1023 configured to exclusively output the PWM signal.

Referring to FIG. 17 together, FIG. 17 is a schematic block diagram ofan optical encoder 17 according to one embodiment of the presentdisclosure. Similarly, the optical encoder 17 includes a displacementgenerating unit (e.g., the element 11/31/41/51 as shown in FIGS. 1 and3-5 ) having a detection surface 107, an optical navigation module 10and a back-end circuit 103.

The detection surface 107 (as shown in FIGS. 16A-16B) of thedisplacement generating unit is formed with a plurality of markers(e.g., one marker M1, M2 being shown herein) at different referencepositions. The plurality of markers may be arranged as a matrix on thedetection surface 107 or arranged only at a few reference positionsaccording to different applications.

When more markers are used, the optical encoder 17 is able to determinemore absolute positions or angles corresponding to the referencepositions of the markers. In this embodiment, the optical encoder 17 isused to determine the absolute position of the optical navigation module10 with respect to the detection surface 107 when a complete or partialimage of one of the plurality of markers is captured. In someembodiments, it is possible to form only one marker on the detectionsurface 10.

For example, the marker M1 in FIG. 16A has 3 longitudinal darker regions(3 brighter regions being formed accordingly) having different widthsand at different locations, and the marker M2 in FIG. 16B has 5longitudinal darker regions (4 brighter regions being formedaccordingly) having different widths and at different locations. Itshould be mentioned that it is possible that the darker/brighter regionsall have different widths or a part of the darker/brighter regions haveidentical widths. It is also possible that all darker/brighter regionshave identical widths but at different locations.

In other words, the marker(s) has patterned lines (e.g., L1˜L5 in FIG.16A) each formed between a first blackness region and a second blacknessregion of the marker(s). The manufacturing of the blackness region ofthe markers M1 and M2 has been mentioned above, e.g., printed by aprinter, but not limited thereto. In this embodiment, the firstbrightness and the second brightness do not have particular limitationsas long as the processing unit 1021 is able to distinguish theirdifference in the captured image. Preferably, the first blackness is0%˜30% blackness and the second blackness is 70%˜100% blackness, but notlimited thereto. In some embodiments, the marker is all black (or thesecond blackness) or all white (or the first blackness), such that thepulse width of the PWM signal is determined according to two edges(described below using an example) of the captured image. In this case,other locations instead of the marker on the detection surface 107 havedifferent blackness from the first and second blackness to bedistinguishable from the marker.

FIGS. 16A and 16B show that the optical navigation module 10 includes alight sensing unit 1020 and a processing unit 1021. In otherembodiments, the optical navigation module 10 also has a light emittingunit (as shown in FIG. 2 ) configured to illuminate the detectionsurface 107 if ambient light is not strong enough or to improve theimage quality. Details of the light emitting unit have been describedabove, and thus details thereof are not repeated herein.

The light sensing unit 1020 is configured to detect a marker (e.g., M1or M2) at a reference position on the detection surface 107 to capturean image.

The image (e.g., raw data thereof) is sent to the processing unit 1021for the post-processing. Regarding the post-processing, the processingunit 1021 generates and outputs a pulse width modulated (PWM) signalcorresponding to the marker at the reference position on the detectionsurface 107 being detected. More specifically, the PWM signal herein isused as an image feature of the processing result mentioned above.

For example, the processing unit 1021 receives the raw data of thecaptured image (e.g., pixel-by-pixel) from the light sensing unit 1020and performs the analog-to-digital conversion (e.g., using an ADCconverter) on the raw data to generate digital image data. Then, theprocessing unit 1021 performs the filtering using such as a digitalfilter to improve the signal quality. In some embodiments, theprocessing unit 1021 performs the thresholding, e.g., removing digitalimage data having a gray value smaller than a predetermined threshold,to remove noises. Details of the filtering and thresholding may use anyproper methods without particular limitations. Finally, the processingunit 1021 detects lines in the captured image and processes to generatethe PWM signal corresponding to the detected lines. For example, a lineis identified when a gray value difference between two adjacent pixelsis larger than a predetermined threshold, wherein the predeterminedthreshold is determined, for example, according to the first blacknessand the second blackness being used.

For example referring to FIG. 19A, it is a schematic diagram of acaptured image F and a generated PWM signal corresponding to the imageF. As shown in FIG. 16A, because the marker M1 in FIG. 16A has patternedlines L1˜L5 formed by two different blackness regions, the capturedimage F has corresponding patterns, e.g., detected lines DL1˜DL5associated with the patterned lines L1˜L5. The processing unit 1021generates a PWM signal having two signal levels (e.g., H level and Llevel shown in FIG. 19A) each has a pulse width corresponding to a pixeldistance between two detected lines in the captured image F or betweenan edge (e.g., IE1 and IE2) of the captured image F and one detectedline in the captured image F. Values of the signal levels L and H arenot particularly limited as long as they are identifiable.

For example, the processing unit 1021 generates a pulse width T4 (havinga high signal level H) corresponding to a pixel distance D4 between thedetected lines DL3 and DL4, and a pulse width T1 (having a low signallevel L) corresponding to a pixel distance D1 between the detected lineDL1 and the edge IE1 in the captured image F. Other pulse widths T2, T3,T5, T6 are also associated with the corresponding pixel distances. Forexample, the optical encoder 17 has a clock circuit (not shown) forgenerating clock signals based on a clock period. In some embodiments,the processing unit 1021 generates the pulse width T4 or T1 as one clockperiod (or a ratio or multiple of one clock period) when the pixeldistance between detected lines DL3 and DL4 or between the detected lineDL1 and the edge IE1 is one pixel size. More pixels of the pixeldistance, the longer the pulse width is generated, e.g., positivecorrelated. Accordingly, the processing unit 1021 is able to determineone complete PWM signal based on the pixel distances between IE1 andDL1, between DL1 and DL2, between DL2 and DL3, between DL3 and DL4,between DL4 and DL5, and between DL5 and IE2. As the generated PWMsignal is determined according to the captured image F of the marker,the PWM signal is used as the encoded signal corresponding to encodedpattern of the markers. The back-end circuit 103 is arranged to be ableto recognize different markers based on the different PWM encodedsignals.

As mentioned above, the optical encoder 17 of the present disclose isoperated in a registration mode or a comparison mode according to anoperating state thereof. Details of entering the registration mode andthe comparison mode (e.g., FIG. 7 a and corresponding descriptions) havebeen described above, and thus details thereof are not repeated herein.Only operations in the registration mode and the comparison mode of thisembodiment are described hereinafter.

In the registration mode, the PWM signal generated by the processingunit 1021 is configured to be stored in a memory 1031 of the back-endcircuit 103 as predetermined PWM signals (i.e. the image feature)corresponding to each of the plurality of markers at different referencepositions. The memory 1031 includes a volatile memory (e.g., RAM) fortemporarily store the data send from the processing unit 1021. Thememory 1031 also includes a non-volatile memory (e.g., ROM) for storingalgorithm(s) for comparing the current PWM signal and the predeterminedPWM signal, and generating the control signal according to a comparisonresult. The algorithm(s) may be implemented by hardware and/or softwarewithout particular limitations.

In the comparison mode, the PWM signal, which corresponds to the markersat the different reference positions on the detection surface 107,generated by the processing unit 1021 is outputted to the back-endcircuit 103. The microcontroller (MCU) 1033 compares (using the built-inalgorithm) the outputted PWM signal (i.e. current PWM signal) with thepredetermined PWM signal (accessing the stored data in the memory 1031)to determine a current position or angle of the optical navigationmodule 10 with respect to the detection surface 107. For example, themicrocontroller 1033 determines whether the current PWM signal matchesany one of the stored PWM signals in the memory 1031 to determinewhether a predetermined PWM signal is detected. If the predetermined PWMsignal is not identified, the light sensing unit 1020 continuouslycaptures another image to be outputted to the MCU 1033 till thepredetermined PWM signal is identified or the operation is ceased by theuser.

In some embodiments, the microcontroller 1033 is able to compare one PWMsignal with the stored PWM signals. In other embodiments, themicrocontroller 1033 is able to compare more than one PWM signalsimultaneously with the stored PWM signals, i.e. the light sensing unit1020 having a larger field of view to capture an image F containing morethan one marker at a time.

Referring to FIG. 18 , it is a schematic diagram of the opticalnavigation module 10 applied to a rotatable detection surface 302 b asshown in FIG. 8 b . There are 4 markers shown on the rotatable detectionsurface 302 b in this case. In this embodiment, the optical encoder 17pre-stores image features, e.g., predetermined PWM signals,corresponding to the markers M0, M90, M180 and M270 (having differentpatterned lines) in the registration mode. In the comparison mode, whenthe processing unit 1021 obtains, according to the frame processingresults, a current PWM signal of a current image matching one of thepredetermined PWM signals, it means that the optical navigation module10 passes or is right above a specific marker such that an absoluteposition (or angle) of the optical navigation module 10 is determined.It is appreciated that although FIG. 18 shows 4 markers being formed orprinted at different angles (e.g., 0, 90, 180, 270 degrees herein) onthe detection surface 302 b, the present disclosure is not limitedthereof. The number of the markers and positions are determinedaccording to different applications, e.g., the identifiable angle.

It is appreciated that the processing unit 1021 and the back-end circuit103 respectively have a communication interface and a built-in(predefined) protocol to communicate with each other. Preferably, theprocessing unit 1021 further generates a start signal in front of thePWM signal as a header to indicate the starting of the PWM signal and anend signal behind the PWM signal to indicate the ending of the PWMsignal. The number of bits of the start signal and end signal is notparticularly limited as long as it is identifiable by the back-endcircuit 103. For example, FIG. 16A shows a PWM signal having a startsignal, pulse widths t₁-t₆ and a stop signal; FIG. 16B shows a PWMsignal having a start signal, pulse widths t₁′-t₉′ and a stop signal.Accordingly, the microcontroller 1033 is able to correctly receivedifferent PWM signals.

Referring to FIG. 19B, it is a schematic diagram of a captured image Fand a generated PWM signal according to another embodiment of thepresent disclosure. In some conditions, a sampling rate of themicrocontroller 1033 is slower than a frequency of the processing unit1021 for generating the PWM signal. In this case, in order to allow themicrocontroller 1033 to accurately acquire the PWM signal, theprocessing unit 1021 further uses a register to repeatedly generate eachbit of the PWM signal for more than one times, such that the pulse widthof each signal level is extended. For example, the pulse widths T1 andT4, among other pulse widths, in FIG. 19A are both shown to be extendedto sT1 and sT4 as shown in FIG. 19B, wherein “s” is a positive number.The value of “s” is determined according to the difference between thesampling rate of the microcontroller 1033 and the clock frequency of theprocessing unit 1021. That is, the output frequency of every bit of thePWM signal seems to be slowed by “s” times such that the microcontroller1033 is able to sample the PWM signal accurately. More specifically, inthe present disclosure, the processing unit 1021 generates the pulsewidth (e.g., t1-t6 in FIG. 16A and t1′-t9′ in FIG. 16B) by multiplying ascale (e.g., “s” in FIG. 19B) to the pixel distance between detectedlines (e.g., DL1-DL5 in FIG. 19A) and the image edges (e.g., IE1 andIE2) in the captured image F, and the scale is larger than or equal to1.

In an alternative embodiment, if the optical navigation module 10 hasthe ability to calculate the pixel gray level in a sub-pixel level, thegenerated PWM signal can be used to confirm the finer position.Referring to FIG. 20 , it is a schematic diagram of an image F capturedby the light sensing unit 1020 and the corresponding PWM signal. In thiscase, the processing unit 1021 does not generate each pulse width basedon the pixel scale but on sub-pixel scale. For example, if theprocessing unit 1021 is arranged to generate a bit “0” corresponding tothe bright region and generate a bit “1” corresponding to the darkregion, the processing unit 1021 does not generate the PWM signal as“00100” but generates the PWM signal as “0000 0000 0111 1000 0000” (i.e.4 bits for one pixel) such that the generated PWM signal has theimproved resolution. In the right hand part of FIG. 20 , the dashed linerefers to a PWM signal without sub-pixel shift, and the solid linerefers to a PWM signal having a sub-pixel shift.

For example, when the processing unit 1021 firstly identifies a positioncorresponding to the PWM signal as “00100”, this position is identifiedas a rough position on the detection surface 107 (e.g., 0 degree in FIG.18 ). Then, the processing unit 1201 generates another PWM signal as“0000 0000 0111 1000 0000” in order to identify a fine tune value (e.g.,1 or −1 degree in FIG. 18 ) according to a position shift of the pulsewidth(s) between the start and end signals. In this case, a value of thefine tune value is recognizable according to a time difference betweent_(B) and t_(B)′ (e.g., between rising edges or falling edges), and adirection of the fine tune value is recognizable according to acomparison between t_(A) and t_(A)′ as well as between t_(C) and t_(C)′.For example, if t_(A)>t_(A)′ and t_(C)<t_(C)′, the direction isdetermined as toward right as in FIG. 20 ; but if t_(A)<t_(A)′ andt_(C)>t_(C)′, the direction is determined as toward left. Therelationship of the increment and decrement of the angle with respect toa direction of the position shift is arranged previously. In thisembodiment, the processing unit 1201 may generate the PWM signal withsub-pixel scale using a register therein. It is also possible that therough position is not determined at first but directly determine thefine position.

In other embodiments, it is possible to identify said direction bycomparing the PWM signals between two successive images F captured bythe light sensing unit 1020, e.g., comparing the positions of T_(B).

In an alternatively embodiment, the microcontroller 1033 recognizes apredetermined sequence of different PWM signals corresponding todifferent markers outputted from the optical navigation module 10.Referring to FIG. 21 , it is a schematic diagram of the arrangement ofthe optical navigation module 10 with respect to a plurality of markers(e.g., markers 0-7) according to another embodiment of the presentdisclosure. The markers 0-7 are divided into different areas bounded bypatterned lines based on a first blackness region (e.g., bright regions)and a second blackness region (e.g., dark regions). The processing unit1021 is also able to generate the PWM signal as shown in FIGS. 16A and16B according to the image F of the markers captured by the opticalnavigation chip 102. For example, if the back-end circuit 103sequentially recognizes “S PWM5 P S PWM4 P S PWM7 P S PWM5 P”, theback-end circuit 103 performs a predetermined control, e.g., unlocking asmart lock, and otherwise the back-end circuit 103 continuously performsthe recognition till a predetermined sequence is identified. In FIG. 21, “S” is referred to the start bit(s), “P” is referred to the endbit(s), PWM4, PWM5 and PWM7 are referred to the PWM signal generatedcorresponding to the markers 4, 5 and 7, respectively. For example, thePWM4 is “0110”, the PWM5 is “0010” and PWM7 is “0001”, wherein “0” islow signal level and “1” is high signal level. More specifically, in thepresent disclosure, the microcontroller 1033 is further configured torecognize a predetermined sequence of different PWM signalscorresponding to different markers outputted from the optical navigationmodule 10. The operations shown in FIGS. 19A-19B and 20 are alsoapplicable to FIG. 21 .

Referring to FIG. 22 , it is a flow chart of an operating method of anoptical encoder according to one embodiment of the present disclosure.The operating method is adaptable to the optical encoder 17 shown inFIGS. 16A-16B and 17 . The operating method of this embodiment includesthe steps of: storing, in a registration mode, a predetermined pulsewidth modulated (PWM) signal corresponding to a marker at a referenceposition on a detection surface in a memory (Step S2201); and comparing,in a comparison mode, a current PWM signal with the predetermined PWMsignal to determine a current position with respect to the detectionsurface (Step S2203). It should be mentioned that this operating methodis also application to identify more than one marker.

As mentioned above, the predetermined PWM signal and the current PWMsignal are both generated by a processing unit 102 of the opticalencoder 17, only they are generated in different modes and havedifferent purposes. It is appreciated that the back-end circuit 103 isarranged to know which of the registration and comparison modes iscurrently operated, e.g., by receiving a trigger signal. Referring toFIG. 19A again, the predetermined PWM signal and the current PWM signalrespectively have two signal levels (e.g., H and L) each has a pulsewidth (e.g., T1-T6) corresponding to a pixel distance between twodetected lines (e.g., DL1-DL5), each of which is associated with apatterned line (e.g., L1˜L5 in FIG. 16A) which is formed between a firstblackness region and a second blackness region of the marker (e.g., M1in FIG. 16A), in a captured image F from the light sensing unit 1020 orbetween an edge (e.g., IE1 and IE2) of the captured image F and onedetected line in the captured image F. Definitions of the first andsecond blackness have been described above, and thus details thereof arenot repeated herein. As mentioned above, the patterned lines are notlimited to be straight lines.

Furthermore, in order to allow the back-end circuit 103 is able tocorrectly acquire the outputted PWM signal from the processing unit1021, the operating method further includes the steps of: generating astart signal in front of the PWM signal by the processing unit 1021, andgenerating an end signal behind the PWM signal by the processing unit1021. The function of the start and end signals is mentioned above, andthus details thereof are not repeated herein.

Furthermore, in order to expand the application of the optical encoder17 of the present disclosure, in addition to identifying an absoluteposition or angle of the optical navigation module 10 with respect to adetection surface 107 of a displacement generating unit, the operatingmethod further includes the step of: recognizing a predeterminedsequence of different PWM signals corresponding to different markers.The sequence of the PWM signals can be used to unlock a smart lock orother applications using the detected sequence of the PWM signals as thecoding/decoding mechanism. Preferably, a time interval between twosuccessively detected PWM signals is within a predetermined time period.When the predetermined time period is exceeded, the predeterminedsequence of the PWM signals is reset from the first one of thepredetermined sequence.

It should be mentioned that although the brighter regions of the markerare associated with low signal levels L and the darker regions of themarker are associated with high signal levels H in the aboveembodiments, it is only intended to illustrate but not to limit thepresent disclosure. It is possible that the brighter regions of themarker are associated with high signal levels and the darker regions ofthe marker are associated with low signal levels.

It should be mentioned that although the patterned lines (e.g., L1-L5 inFIG. 16A) herein are shown as longitudinal lines, the present disclosureis not limited thereto. In other embodiments, it is possible that thepatterned lines are formed by transverse lines or formed by acombination of longitudinal lines and transverse lines as long as thealgorithm capable of recognizing the patterned lines are previouslybuilt-in the processing unit 1021 by software coding and/or hardwarecoding.

It should be mentioned that although FIGS. 16A-16B and 19A-19B show onlytwo signal levels, the present is not limited thereto. In otherembodiments, the PWM signals have more than two signal levels aregenerated respectively corresponding to the regions of the markerencoded by more than two different blackness (e.g., referring to FIG. 14) as long as the optical encoder 17 has the ability to distinguish saiddifferent blackness regions.

Although the disclosure has been explained in relation to its preferredembodiment, it is not used to limit the disclosure. It is to beunderstood that many other possible modifications and variations can bemade by those skilled in the art without departing from the spirit andscope of the disclosure as hereinafter claimed.

What is claimed is:
 1. An optical encoder, comprising: a displacementgenerating unit, having a detection surface formed with a marker at areference position, the marker being divided into multiple areas, saidmultiple areas of the marker being arranged to have a predeterminedcombination of bright regions and dark regions; an optical navigationmodule, comprising: a light sensing unit, configured to capture an imagecontaining the marker; and a processing unit, configured to output apulse width modulated (PWM) signal corresponding to the predeterminedcombination of the marker at the reference position on the detectionsurface, wherein the PWM signal has two signal levels corresponding tothe predetermined combination in the captured image; and a back-endcircuit, configured to determine an original position of the opticalnavigation module with respect to the detection surface according to theoutputted PWM signal.
 2. The optical encoder as claimed in claim 1,further comprising a light emitting unit configured to illuminate thedetection surface.
 3. The optical encoder as claimed in claim 1, whereinthe processing unit is integrated in a chip which has a pin configuredto exclusively output the PWM signal.
 4. The optical encoder as claimedin claim 1, wherein the processing unit is further configured togenerate a start signal in front of the PWM signal and an end signalbehind the PWM signal.
 5. The optical encoder as claimed in claim 4,wherein the back-end circuit is further configured to identify a finetune value according to a position shift of a pulse width between thestart and end signals.
 6. The optical encoder as claimed in claim 1,wherein the bright regions and the dark regions have an arc shape or arectangular shape.
 7. An optical encoder, comprising: a displacementgenerating unit, having a detection surface formed with a marker at areference position, the marker being divided into multiple areas, saidmultiple areas of the marker being arranged to have a predeterminedcombination of first blackness regions and second blackness regions; anoptical navigation module, comprising: a light sensing unit, configuredto capture an image containing the marker; and a processing unit,configured to output, in a comparison mode, a pulse width modulated(PWM) signal corresponding to the predetermined combination of themarker at the reference position on the detection surface, wherein thePWM signal has two signal levels corresponding to the predeterminedcombination in the captured image; and a back-end circuit comprising: amemory, configured to store a predetermined PWM signal corresponding tothe marker at the reference position; and a microcontroller, configuredto compare the outputted PWM signal with the predetermined PWM signal todetermine an original position of the optical navigation module withrespect to the detection surface.
 8. The optical encoder as claimed inclaim 7, wherein the predetermined PWM signal is generated by theprocessing unit in a registration mode.
 9. The optical encoder asclaimed in claim 7, wherein the first blackness is 0%˜30% blackness andthe second blackness is 70%˜100% blackness.
 10. The optical encoder asclaimed in claim 7, wherein the processing unit is further configured togenerate a start signal in front of the outputted PWM signal and an endsignal behind the outputted PWM signal.
 11. The optical encoder asclaimed in claim 10, wherein the microcontroller is further configuredto identify a fine tune value according to a position shift of a pulsewidth between the start and end signals.
 12. The optical encoder asclaimed in claim 7, wherein the processing unit is integrated in a chipwhich has a pin configured to exclusively output the PWM signal to theback-end circuit.
 13. The optical encoder as claimed in claim 7, whereinthe first darkness regions and the second darkness regions have an arcshape or a rectangular shape.
 14. An optical encoder, comprising: adisplacement generating unit, having a detection surface formed with amarker at a reference position, the marker having patterned lines eachformed between a bright region and a dark region of the marker; anoptical navigation module, comprising: a light sensing unit, configuredto capture an image by receiving reflected light from the marker; and aprocessing unit, configured to output a pulse width modulated (PWM)signal corresponding to the marker at the reference position on thedetection surface, wherein the PWM signal has two signal levels each hasa pulse width corresponding to a pixel distance between two detectedlines in the captured image or between an edge of the captured image andone detected line in the captured image; and a back-end circuit,configured to determine an original position of the optical navigationmodule with respect to the detection surface according to the outputtedPWM signal.
 15. The optical encoder as claimed in claim 14, wherein theprocessing unit is further configured to generate a start signal infront of the PWM signal and an end signal behind the PWM signal.
 16. Theoptical encoder as claimed in claim 14, wherein the processing unit isintegrated in a chip which has a pin configured to exclusively outputthe PWM signal to the back-end circuit.
 17. The optical encoder asclaimed in claim 14, wherein the processing unit is configured togenerate the pulse width by multiplying a scale to the pixel distance,and the scale is larger than or equal to 1.